Tool organizer and tool organizer module

ABSTRACT

A tool organizer module includes a base defining an opening to receive a magnet and a feature to receive a portion of a tool and a magnet disposed in the opening of the base.

This disclosure relates generally to tools, and, more particularly, todevices for organizing tools.

BACKGROUND

Tools are typically housed in a toolbox drawer or tray which may includepartitions to define subsections in which tools such as screwdrivers,socket wrenches, sockets and the like may be arranged. When selectedtools are required for a task, the entire toolbox is typically moved tothe worksite.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1C are schematic illustrations of an example first toolorganizer module constructed in accordance with teachings of thisdisclosure.

FIG. 1D is a schematic illustration of an example second tool organizermodule constructed in accordance with teachings of this disclosure.

FIGS. 2A-2B are schematic illustrations of an example third toolorganizer module constructed in accordance with teachings of thisdisclosure.

FIG. 2C is a schematic illustration of the example third tool organizermodule of FIGS. 2A-2B, constructed in accordance with teachings of thisdisclosure, bearing an example tool.

FIG. 3A is a schematic illustration of an example first tool organizerconstructed in accordance with teachings of this disclosure.

FIG. 3B is a schematic illustration of the example first tool organizerof FIG. 3A bearing a plurality of example first tool organizer modulesof FIGS. 1A-1C constructed in accordance with teachings of thisdisclosure.

FIGS. 4A-4B are schematic illustrations of an example second toolorganizer constructed in accordance with teachings of this disclosure.

FIG. 4C is a schematic illustration of the example second tool organizerof FIGS. 4A-4B bearing a plurality of example first tool organizermodules of FIGS. 1A-1C constructed in accordance with teachings of thisdisclosure.

FIG. 5 is a schematic illustration of an example toolbox includingexample first tool organizer modules of FIGS. 1A-1C and example thirdtool organizer modules of FIGS. 2A-2C constructed in accordance withteachings of this disclosure.

FIG. 6 is a flowchart illustrating an example use of the example first,second or third tool organizer modules in combination with the first orthe second tool organizers in accordance with teachings of thisdisclosure.

The figures are not to scale. Wherever possible, the same referencenumbers will be used throughout the drawing(s) and accompanying writtendescription to refer to the same or like parts. As used in this patent,stating that any part is in any way positioned on (e.g., positioned on,located on, disposed on, etc.) another part, indicates that thereferenced part is either in contact with the other part, or that thereferenced part is above the other part with one or more intermediatepart(s) located therebetween. Stating that any part is in contact withanother part means that there is no intermediate part between the twoparts.

DETAILED DESCRIPTION

Toolboxes can become quite cluttered and disorganized, particularlywhere there is a mismatch between a number of compartments within atoolbox and a number of and/or size of tools (e.g., socket wrenches,sockets, etc.) to be stored therein.

FIGS. 1A-1C are schematic illustrations of an example first toolorganizer module 100 including an example base 105 defining one or moreexample features 110 to receive a portion of a tool. In some examples,the base 105 is square, such as is shown in FIGS. 1A-1C. In someexamples, the base 105 is substantially square, rectangular, round, orpolygonal, having three or more sides (e.g., triangular, pentagonal,octagonal, etc.).

In some examples, the feature 110 includes a post extending from anexample upper surface of the base 105, such as is shown in FIGS. 1A-1D.In some examples, the feature 110 includes a recession in the upperportion corresponding in shape and size to a shape and size of a tool tobe received therein. For instance, the feature 110 may include anannular recess in the upper portion dimensioned to receive a socket of aparticular size (e.g., a 16 mm socket, a ¾″ socket, etc.).

In some examples, the feature 110 includes a cylindrical post having anouter diameter corresponding to an inner diameter of the portion of thetool to be received. In some examples, the feature 110 includes apolygonal (e.g., a triangular, square, pentagonal, hexagonal, octagonal,12-sided, etc.) post having an outer dimension corresponding to an innerdimension of the portion of the tool to be received. For instance, thefeature 110 may be a square post corresponding in dimension to (e.g.,slightly smaller than, etc.) a driver hole or square hole of a socket(e.g., ¼″, ⅜″, ½″, ¾″, 1″, etc.) or a socket head (e.g., a 6-pointsocket head, a 12-point socket head, etc.). In some examples, thefeature 110 includes a lobed shape (e.g., pentalobe, etc.), across-shape or a star-shape (e.g., a 6-pointed star, an 8-pointed star,etc.). A length of the feature 110 may also vary to correspond to adesired application. For instance, a first tool organizer module 100 mayinclude a feature 110 having a first length for a first tool 130 (e.g.,a standard socket), a second length for a second tool 130 (e.g., asemi-deep socket) or a third length for a third tool 130 (e.g., a deepsocket). In some examples, the first tool organizer module 100 andcorresponding feature 110 are constructed to accommodate any type ofsocket or attachment for any socket drive wrench (e.g., standard,metric, deep-well, impact, Allen, Torx, drive extensions, etc.).

FIG. 1B shows the first tool organizer module 100 in an invertedposition to show, at a bottom portion thereof, that the base 105 definesan example opening 120 to receive an example magnet 125. The magnet 125is shown adjacent the base 105 of the first tool organizer module 100and the arrow A1 indicates that the magnet 125 is to be inserted intothe opening 120. In some examples, the base 105 defines a plurality ofopenings 120 to receive a corresponding plurality of magnets. In someexamples, the magnet 125 is circular or cylindrical in shape. In someexamples, the magnet 125 is a polygonal shape (e.g., square, etc.).

In some examples, the magnet 125 is retained within the opening via afriction fit or interference fit between a periphery of the magnet 125and the surface of or surfaces of the opening 120. In some examples, themagnet 125 is retained within the opening via an adhesive applied to themagnet 125 and/or the surface(s) of the opening 120 prior to insertionof the magnet 125 into the opening 120. In some examples, a retainer(not shown) is attached to a bottom of the base 105 to retain the magnet125 in the opening 120. In some examples, the retainer is connected tothe bottom of the base 105 via an adhesive or via a snap-fit connectionincluding one or more male-female connectors. For instance, the base 105includes one or more connectors (e.g., female connector(s), maleconnector(s), a combination of male connector(s) and femaleconnector(s)) positioned to matingly connect with one or morecorresponding connectors (e.g., male connector(s), female connector(s),a combination of female connector(s) and male connector(s)) provided onthe retainer. In some examples, the magnet 125 includes a rare-earthmagnet (e.g., a neodymium magnet, etc.), an Alnico alloy or a ferrite.In some examples, the magnet 125 is integrally formed within the firsttool organizer module 100.

In some examples, recesses 115 are formed in one or more sides of thefirst tool organizer module 100. In some examples, the recesses 115facilitate handling of the first tool organizer module 100 and/orfacilitate removal of the first tool organizer module 100 from a toolorganizer, enabling improved purchase of the edges of the base 105. Inthe example first tool organizer module 100 of FIGS. 1A-1D, a recess 115is formed in each side of the base 105.

FIG. 1C shows an example tool 130, a socket, moved into position on thefeature 110, shown as a cylindrical post extending from an example uppersurface of the base 105. In this example, a diameter of the feature 110is substantially equal to a length of a side of a square hole at thedriven end of the tool 130 (e.g., less than about ¼″, less than about⅜″, less than about ½″, etc.). In some examples, the feature 110provides a clearance fit or a transition fit with the tool 130 enablingthe tool 130 to be readily assembled with and disassembled from thefeature 110 while still providing securement of the tool 130 about thefeature 110. In some examples, where the tool 130 is itself ferrous,ferritic or magnetic, an additional retention force is imparted by themagnet 125.

FIG. 1D is a schematic illustration of an example second tool organizermodule 140 including an example base 145, rectangular in the example ofFIG. 1D, defining a first example feature 150 and a second examplefeature 155. Each of the first feature 150 and the second feature 155are configured to receive a portion of a tool, as is described above inrelation to feature 110. In some examples, the first feature 150 and thesecond feature 155 are the same configuration. For example, the firstfeature 150 and the second feature 155 each include an approximately ⅜″square post to receive the square hole of tools 130 (e.g., ⅜″ sockets)having different sizes. In some examples, the first feature 150 and thesecond feature 155 are different configurations. For example, the firstfeature 150 and the second feature 155 are sized to accommodate a6-point or 12-point socket having different sizes (e.g., 10 mm, 13 mm).

Example recesses 160 are formed in one or more sides of the base 145 ofthe second tool organizer module 140. As noted above, the recesses 160facilitate handling of the first tool organizer module 100 and/orfacilitate removal of the first tool organizer module 100 from a toolorganizer, enabling improved purchase of the edges of the base 105.

In some examples, the second tool organizer module 140 includes one ormore magnets (not shown) retained within one or more openings in thebase 145. In some examples, a first magnet is disposed in a firstopening formed beneath the first feature 150 and a second magnet isdisposed in a second opening formed beneath the second feature 155. Insome examples, a single magnet is disposed in an opening in the base 145that is adjacent the first feature 150 and the second feature 155, suchas between the first feature 150 and the second feature 155. As notedabove with respect to FIGS. 1A-1C, the magnet(s) may be retained withinthe opening(s) via an adhesive, an interference or friction fit, via aretainer (not shown) attached to a bottom of the base 145 and/or sidesof the base 145. Alternatively, the magnet may be integrally formedwithin the second tool organizer module 140.

Similarly, in other examples, the second tool organizer module 140 mayinclude three or more features 110. While the first feature 150 and thesecond feature 155 are shown to be aligned linearly along the base 145,the second tool organizer module 140 may include three or more features110 that are not aligned and the base 145 may assume another geometry(e.g., triangular, square, round, etc.).

In some examples, the feature 110 of the first tool organizer module 100and/or the second tool organizer module 140 may include a stake, pin orpost about which the feature 110 is removably attached. For example, auser is permitted to remove a first feature 110 from the first toolorganizer module 100 and replace it by attaching a second feature 110 tothe stake, pin or post to reconfigure the first tool organizer module100, if desired.

FIGS. 2A-2B are schematic illustrations of an example third toolorganizer module 200. The third tool organizer module 200 includes anexample base 202 defining an example feature 210 to receive a portion ofa tool. In FIGS. 2A-2C, the base 202 is substantially rectangular. Insome examples, the base 202 is square or substantially square.

In the third tool organizer module 200, the feature 210 includes achannel extending across the upper portion of the base 202. In theexample of FIGS. 2A-2C, the channel includes sloped and convergentsides, with a first side 215 and a second side 220 angling downwardlyfrom a first shoulder 222 and a second shoulder 224, respectively, at anupper portion of the base 202 to converge at an example valley 230. Asshown in FIGS. 2A-2C, the base 202 is elongated along a direction of thefeature 210 (e.g., along the channel).

FIG. 2B shows the third tool organizer module 200 in an invertedposition. An example lower portion of the base 202 defines exampleopenings 240 to receive example magnets 245 therein. While threeopenings 240 and three magnets 245 are shown in the example third toolorganizer module 200, a greater number or a lesser number (e.g., one,two) of openings 240 and magnets 245 could be provided. As with theprior example of FIGS. 1A-1D, the magnets 245 are retained within theopenings 240 via a friction fit or interference fit between a peripheryof the magnets 245 and the surface of or surfaces of the openings 240.Likewise, in some examples, the magnets 245 are retained within theopening via an adhesive applied to the magnets 245 and/or the surface(s)of the openings 240 prior to insertion of the magnets 245 into theopenings 240. Additionally, in some examples, a retainer (not shown) isattached to a bottom of the base 202 to retain the magnets 245 in theopenings 240. In some examples, the retainer is connected to the bottomof the base 202 via an adhesive or via a snap-fit connection includingone or more male-female connectors, such as is described above inrelation to FIGS. 1A-1D. In some examples, the magnets 245 include arare-earth magnet (e.g., a neodymium magnet, etc.), an Alnico alloy or aferrite.

FIG. 2C shows an example tool 260, a screwdriver, moved into position onthe feature 210, shown as a channel extending from a first end of thethird tool organizer module 200 to a second end of the third toolorganizer module 200. In this example, a magnetic force from the magnets245 adheres the shank of the screwdriver to the valley 230 and/or thefirst side 215 and the second side 220 of the feature 210. In someexamples, the tool 260 is itself ferrous, ferritic or magnetic,enhancing securement of the tool 260 within the feature 210. In someexamples, the tool 260 includes an elongated metal tool, such as, butnot limited to screw drivers, Torx drivers, socket drives, open andbox-end wrenches, crescent wrenches or Allen wrenches.

In the example of FIGS. 2A-2C, as with the examples of FIGS. 1A-1D, theopenings 240 are formed beneath the feature 210. In some examples, theopenings 240 are formed adjacent the feature 210 (e.g., positionedadjacent a centerline or axis of the feature, etc.). For example, themagnets 245 could include bar magnets disposed in openings (not shown)beneath the first side 215 and the second side 220 or bar magnetsintegrally formed within the third tool organizer module 200.

FIG. 3A is a schematic illustration of an example first tool organizer300. The first tool organizer 300 includes an example handle 310 and anexample elongated substrate 320. In some examples, the elongatedsubstrate 320 is formed from a ferromagnetic metal. In some examples,the elongated substrate 320 includes a ferromagnetic metal. Forinstance, in some examples, the elongated substrate 320 is formed from astiff thermoplastic (e.g., a high-density polyethylene (HDPE), ahomopolymer acetal, a copolymer acetal, etc.) having a ferromagneticmetal formed therein or disposed therein. In some examples, theelongated substrate 320 is in the form of an elongated bar.

The first tool organizer 300 is constructed to accommodate one or moretool organizer modules, such as one or more of the first tool organizermodule 100, one or more of the second tool organizer module 140 and/orone or more of the third tool organizer module 200. The tool organizermodule(s) may be removably attached to a surface of the elongatedsubstrate 320 (e.g., a top surface and/or a bottom surface of theexample elongated substrate 320 shown in FIG. 3A-3B) via a magneticattraction between the magnet(s) (e.g., 125, 245, etc.) of the toolorganizer module(s) (e.g., 100, 140, 200) and the ferromagnetic metal ofthe elongated substrate 320 of the first tool organizer 300. Theelongated substrate 320 is advantageously dimensioned to accommodate aplurality of tool organizer modules (e.g., 100, 140, 200).

FIG. 3B shows the elongated substrate 320 of the first tool organizer300 having a plurality of the first tool organizer modules 100, labeledas 100A-100C, attached to the elongated substrate 320 via a magneticattraction between the magnets 125 of the first tool organizer modules100A-100D and the ferromagnetic metal of the elongated substrate 320.FIG. 3B also shows another first tool organizer module 100, labeled as100E, positioned over the elongated substrate 320 and moving toward theelongated substrate 320, as indicated by the arrow A2, where it will beattached, via a magnetic attraction between the magnets 125 of the firsttool organizer modules 100A-100C and the ferromagnetic metal of theelongated substrate 320. On each of the first tool organizer modules100A-100E are corresponding tools 130A-130E retained on the features 110of each of the respective first tool organizer modules 100A-100E.

In some examples, the elongated substrate 320 includes connectorelements (e.g., notches, male/female connectors, etc.) to permitattachment of an extender element to extend a length of the elongatedsubstrate 320. The extender element enables additional tool organizermodules (e.g., first tool organizer modules 100A-100D, etc.) to becarried by the first tool organizer 300. In some examples the elongatedsubstrate 320 is itself segmented into a plurality of sections that maybe selectively used, or stowed, based on immediate needs of a user.

FIG. 4A is a schematic illustration of an example second tool organizer400. The second tool organizer 400 is in the form of an example bracket.In some examples, the second tool organizer 400 is in the form of anL-bracket. In some examples, the second tool organizer 400 is formedfrom a ferromagnetic metal. In some examples, the second tool organizer400 includes a ferromagnetic metal. For instance, in some examples, thesecond tool organizer 400 is formed from a stiff thermoplastic (e.g.,HDPE, a homopolymer acetal, a copolymer acetal, etc.) having aferromagnetic metal formed therein or disposed therein.

The second tool organizer 400 is constructed to accommodate one or moretool organizer modules, such as one or more of the first tool organizermodule 100, one or more of the second tool organizer module 140 and/orone or more of the third tool organizer module 200. The tool organizermodule(s) may be removably attached to a surface of the second toolorganizer 400 via a magnetic attraction between the magnet(s) (e.g.,125, 245, etc.) of the tool organizer module(s) (e.g., 100, 140, 200)and the ferromagnetic metal of the second tool organizer 400. Forexample, the tool organizer module(s) may be removably attached to anexample upper surface of an example first part 405 or an example uppersurface of an example second part 410. In some examples, the toolorganizer module(s) may be removably attached to a fin 415, or verticalpart of, the second tool organizer 400. For example, the tool organizermodule(s) may be removably attached to an exterior surface of an examplethird part 420 and/or an exterior surface of an example fourth part 425.The second tool organizer 400 is advantageously dimensioned toaccommodate a plurality of tool organizer modules (e.g., 100, 140, 200).

FIG. 4B shows the second tool organizer 400 in an inverted position toshow a bottom portion of the second tool organizer 400. Attached to, orintegrated with, the second tool organizer 400 are one or more magnets430. In some examples, the one or more magnets 430 are attached to(e.g., mechanical fastener, adhesive, weld, etc.), or integrated with,an example lower surface of the first part 405 or an example lowersurface of the second part 410.

FIG. 4C shows the second tool organizer 400 having a plurality of thefirst tool organizer modules 100, labeled as 100A-100J, attached to thesecond tool organizer 400 via a magnetic attraction between the magnets125 of the first tool organizer modules 100A-100C and the ferromagneticmetal of the second tool organizer 400. On each of the first toolorganizer modules 100A-100J are corresponding tools 130A-130J retainedon the features 110 (not shown) of each of the respective first toolorganizer modules 100A-100J. One advantage of the horizontal placementof the first tool organizer modules 100A-100J orients the tools130A-130J horizontally, which minimizes a vertical profile of thecombination, facilitating placement of the second tool organizer 400within a toolbox even when bearing tools 130A-130J (e.g., deep-wellsockets, drive extensions, etc.) are too tall to stand vertically in atoolbox

In some examples, the first tool organizer 300 and/or the second toolorganizer 400 include one or more magnets, or a ferromagnetic materialthat is magnetized, and a base (e.g., 105, 145, 202) the first toolorganizer module 100, the second tool organizer module 140 and/or thethird tool organizer module 200 includes a ferromagnetic metal. In suchexamples, the first tool organizer 300 and/or the second tool organizer400 include one or more magnets integrated therein (e.g., in one or moreopenings, adhesively attached to, welded to, etc.) and a base (e.g.,105, 145, 202) the first tool organizer module 100, the second toolorganizer module 140 and/or the third tool organizer module 200 includesa ferromagnetic metal that is able to be magnetically adhered to theparts and/or surfaces of the first tool organizer 300 and/or the secondtool organizer 400 corresponding to locations of the magnets. In suchexamples, the first tool organizer 300 and/or the second tool organizer400 may advantageously be positioned on and adhered to surfaces adjacenta work site. For instance, an automobile mechanic may magneticallyadhere one or more first tool organizers 300 and/or one or more secondtool organizers 400 to an iron or steel component of an automobile ineasy reach for a task at hand.

FIG. 5 is a schematic illustration of an example toolbox 500 includingfirst tool organizer modules 100A-100N of FIGS. 1A-1C bearing tools130A-130N and third tool organizer modules 200A-200J of FIGS. 2A-2Cbearing tools 260A-260J. FIG. 5 shows an example drawer 510 includingfirst tool organizer modules 100A-100N of FIGS. 1A-1C bearing tools130A-130N and third tool organizer modules 200A-200B of FIGS. 2A-2Cbearing tools 260A-260B. The first tool organizer modules 100A-100L aremagnetically adhered directly to the drawer 510. The first toolorganizer modules 100M-100N are magnetically adhered directly to anexample sidewall 515 of the drawer 510. The horizontal placement of thefirst tool organizer modules 100M-100N orients the tools 130M-130Nhorizontally, as the tools 130M-130N have a length that would not permitthem to be oriented vertically within the drawer 510.

An example upper section 520 of the toolbox 500 has third tool organizermodules 200C-200F of FIGS. 2A-2C magnetically adhered to the uppersection 520. The third tool organizer modules 200C-200F bear tools260C-260F in the features 210 defined therein. An example lid 525 of thetoolbox 500 has third tool organizer modules 200G-200J of FIGS. 2A-2Cmagnetically adhered to an underside of the lid 525. The third toolorganizer modules 200G-200J bear tools 260G-260J in the features 210defined therein. FIG. 5 illustrates the ability of the disclosed firsttool organizer modules 100, second tool organizer modules 140 and thirdtool organizer modules 200 to advantageously utilize all available spacein the toolbox, inclusive of the sides of drawers or trays and/or evenon the underside of a lid of the toolbox 500.

FIG. 6 is a flowchart 600 illustrating an example use of the first toolorganizer module 100, the second tool organizer module 140 and/or thethird tool organizer module 200 in combination with the first toolorganizer 300 or the second tool organizer 400. The flowchart starts atexample block 610 with a selection of a set (i.e., one or more) of toolorganizer modules. At block 610, a selection of a set of tool organizermodules is made from a population of tool organizer modules (e.g., oneor more tool organizer modules) including one or more first toolorganizer modules 100, one or more second tool organizer modules 140and/or one or more third tool organizer modules 200.

At example block 620, a tool organizer is selected. Based on a number ofand type of tool organizer module(s) selected at block 610, one or moretool organizers are selected to from a population of one or more firsttool organizers 300 and/or one or more second tool organizers 400.

At example block 630, the selected tool organizer module(s) selected atblock 610 are attached to the tool organizer(s) selected at block 620via a magnetic adherence between the selected tool organizer module(s)and selected tool organizer(s).

In some examples, the first tool organizer module 100, the second toolorganizer module 140 and/or the third tool organizer module 200 arecolor-coded to facilitate ready identification of tools 130, 260 bornethereby. For example, all tool organizer modules (100, 140, 200) arecolored red to signify tools in English-units or Standard units and arecolored blue to signify tools in Metric-units. Thus, even from afar, auser can determine whether a particular tool (e.g., a socket) isappropriate to a particular task without looking further at a labelborne by the tool organizer modules or a label or etching on the tool.

In some examples, each tool organizer module (100, 140, 200) includes alabel indicating the particular tool to which the tool organizer moduleis configured. For instance, in the example first tool organizer modules100 of FIGS. 1A-1C, an annular label may be disposed about the feature110 (e.g., a socket label of “16 mm 12 pt,” “11/16 12 pt,” “21 mm 6 pt,”etc.). Thus, a set of example first tool organizer modules 100 for a ¼″drive (6 pt metric) could include ten first tool organizer modules 100,each with a ¼″ square post feature 110, for a 5 mm, 5.5 mm, 6 mm, 7 mm,9 mm, 10 mm, 11 mm, 12 mm, 13 mm and 14 mm. In another example, a set ofexample first tool organizer modules 100 for a ½″ drive (12 pt metric)could include twelve first tool organizer modules 100, each with a ½″square post feature 110, for a 11 mm, 12 mm, 13 mm, 14mm, 15 mm, 16 mm,17 mm, 18 mm, 19 mm, 20 mm, 21 mm and 22 mm.

The disclosed examples of FIGS. 1A-5 illustrate a system of toolorganizer modules (e.g., 100, 140, 200) and tool organizers (e.g., 300,400) that are combinable in any manner to organize a toolbox and/or aworkspace. The tool organizer modules (e.g., 100, 140, 200) and toolorganizers (e.g., 300, 400), in combination, ensure that the tools(e.g., 130, 260) borne thereby stay in place even during transport orduring use. For instance, the tool organizers (e.g., 300, 400), whichmay include magnets or may include magnetized material, are able to beadhered to any steel tool box, any steel tool box shelf, a variety ofmetal surfaces in a workshop, or a variety of metal surfaces inside aworking vehicle such as a car, truck or tractor. The disclosed system oftool organizer modules (e.g., 100, 140, 200) and tool organizers (e.g.,300, 400) provide a modular system that is adaptable to the user'sneeds.

Although certain example methods, apparatus and articles of manufacturehave been disclosed herein, the scope of coverage of this patent is notlimited thereto. On the contrary, this patent covers all methods,apparatus and articles of manufacture fairly falling within the scope ofthe claims of this patent.

What is claimed is:
 1. A tool organizer module, comprising: a basedefining an opening to receive a magnet and a feature to receive aportion of a tool; and a magnet disposed in the opening of the base. 2.The tool organizer module of claim 1, wherein the feature includes apost.
 3. The tool organizer module of claim 2, wherein the post iscylindrical and has an outer diameter corresponding to an inner diameterof the portion of the tool to be received.
 4. The tool organizer moduleof claim 2, wherein the post is polygonal and has an outer dimensioncorresponding to an inner dimension of the portion of the tool to bereceived.
 5. The tool organizer module of claim 1, wherein the featureincludes a channel extending across an upper portion of the base.
 6. Thetool organizer module of claim 5, wherein the channel includes slopedand convergent sides.
 7. The tool organizer module of claim 5, whereinthe base is elongated along a direction of the channel.
 8. The toolorganizer module of claim 1, wherein the magnet includes a rare-earthmagnet.
 9. The tool organizer module of claim 1, wherein a lower portionof the base defines a plurality of openings.
 10. The tool organizermodule of claim 9, further including a magnet disposed in each of theplurality of openings.
 11. The tool organizer module of claim 10,wherein the plurality of openings are formed beneath the feature oradjacent the feature.
 12. A tool organizer, comprising: an elongatedsubstrate including a ferromagnetic metal along a first surface of theelongated substrate; and a tool organizer module including a basedefining an opening to receive a magnet and a feature to receive aportion of a tool and including a magnet disposed in the opening of thebase, wherein the tool organizer module is removably attached to thefirst surface of the elongated substrate via a magnetic attractionbetween the magnet of the tool organizer module and the ferromagneticmetal.
 13. The tool organizer of claim 12, wherein the first surface ofthe elongated substrate is dimensioned to accommodate a plurality oftool organizer modules.
 14. The tool organizer of claim 13, furtherincluding the plurality of tool organizer modules.
 15. The toolorganizer of claim 14, wherein the elongated substrate includes anelongated bar or an elongated bracket.
 16. The tool organizer of claim15, wherein the elongated substrate includes a ferromagnetic metal alonga second surface of the elongated substrate.
 17. The tool organizer ofclaim 16, wherein the plurality of tool organizer modules include aplurality of different features.
 18. The tool organizer of claim 17,wherein the plurality of different features includes a plurality ofposts of different dimensions, the plurality of posts of differentdimensions being operable to receive portions of tools having differentdimensions.
 19. A tool organizer, comprising: an elongated substratedefining an opening to receive a magnet and including a magnet disposedin the opening; and a tool organizer module including a base and afeature to receive a portion of a tool, the base including aferromagnetic metal, wherein the tool organizer module is removablyattached to the elongated substrate via a magnetic attraction betweenthe ferromagnetic metal of the tool organizer module and the magnet ofthe elongated substrate.
 20. The tool organizer of claim 19, wherein theelongated substrate is dimensioned to accommodate a plurality of toolorganizer modules.